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1 theory Synopsis |
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2 imports Base Main |
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3 begin |
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4 |
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5 chapter {* Synopsis *} |
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6 |
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7 section {* Notepad *} |
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8 |
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9 text {* |
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10 An Isar proof body serves as mathematical notepad to compose logical |
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11 content, consisting of types, terms, facts. |
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12 *} |
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13 |
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14 |
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15 subsection {* Types and terms *} |
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16 |
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17 notepad |
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18 begin |
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19 txt {* Locally fixed entities: *} |
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20 fix x -- {* local constant, without any type information yet *} |
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21 fix x :: 'a -- {* variant with explicit type-constraint for subsequent use*} |
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22 |
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23 fix a b |
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24 assume "a = b" -- {* type assignment at first occurrence in concrete term *} |
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25 |
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26 txt {* Definitions (non-polymorphic): *} |
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27 def x \<equiv> "t::'a" |
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28 |
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29 txt {* Abbreviations (polymorphic): *} |
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30 let ?f = "\<lambda>x. x" |
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31 term "?f ?f" |
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32 |
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33 txt {* Notation: *} |
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34 write x ("***") |
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35 end |
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36 |
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37 |
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38 subsection {* Facts *} |
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39 |
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40 text {* |
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41 A fact is a simultaneous list of theorems. |
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42 *} |
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43 |
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44 |
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45 subsubsection {* Producing facts *} |
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46 |
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47 notepad |
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48 begin |
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49 |
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50 txt {* Via assumption (``lambda''): *} |
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51 assume a: A |
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52 |
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53 txt {* Via proof (``let''): *} |
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54 have b: B sorry |
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55 |
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56 txt {* Via abbreviation (``let''): *} |
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57 note c = a b |
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58 |
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59 end |
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60 |
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61 |
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62 subsubsection {* Referencing facts *} |
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63 |
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64 notepad |
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65 begin |
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66 txt {* Via explicit name: *} |
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67 assume a: A |
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68 note a |
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69 |
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70 txt {* Via implicit name: *} |
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71 assume A |
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72 note this |
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73 |
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74 txt {* Via literal proposition (unification with results from the proof text): *} |
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75 assume A |
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76 note `A` |
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77 |
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78 assume "\<And>x. B x" |
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79 note `B a` |
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80 note `B b` |
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81 end |
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82 |
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83 |
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84 subsubsection {* Manipulating facts *} |
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85 |
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86 notepad |
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87 begin |
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88 txt {* Instantiation: *} |
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89 assume a: "\<And>x. B x" |
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90 note a |
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91 note a [of b] |
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92 note a [where x = b] |
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93 |
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94 txt {* Backchaining: *} |
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95 assume 1: A |
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96 assume 2: "A \<Longrightarrow> C" |
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97 note 2 [OF 1] |
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98 note 1 [THEN 2] |
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99 |
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100 txt {* Symmetric results: *} |
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101 assume "x = y" |
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102 note this [symmetric] |
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103 |
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104 assume "x \<noteq> y" |
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105 note this [symmetric] |
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106 |
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107 txt {* Adhoc-simplification (take care!): *} |
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108 assume "P ([] @ xs)" |
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109 note this [simplified] |
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110 end |
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111 |
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112 |
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113 subsubsection {* Projections *} |
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114 |
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115 text {* |
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116 Isar facts consist of multiple theorems. There is notation to project |
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117 interval ranges. |
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118 *} |
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119 |
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120 notepad |
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121 begin |
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122 assume stuff: A B C D |
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123 note stuff(1) |
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124 note stuff(2-3) |
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125 note stuff(2-) |
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126 end |
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127 |
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128 |
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129 subsubsection {* Naming conventions *} |
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130 |
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131 text {* |
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132 \begin{itemize} |
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133 |
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134 \item Lower-case identifiers are usually preferred. |
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135 |
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136 \item Facts can be named after the main term within the proposition. |
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137 |
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138 \item Facts should \emph{not} be named after the command that |
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139 introduced them (@{command "assume"}, @{command "have"}). This is |
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140 misleading and hard to maintain. |
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141 |
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142 \item Natural numbers can be used as ``meaningless'' names (more |
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143 appropriate than @{text "a1"}, @{text "a2"} etc.) |
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144 |
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145 \item Symbolic identifiers are supported (e.g. @{text "*"}, @{text |
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146 "**"}, @{text "***"}). |
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147 |
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148 \end{itemize} |
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149 *} |
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150 |
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151 |
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152 subsection {* Block structure *} |
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153 |
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154 text {* |
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155 The formal notepad is block structured. The fact produced by the last |
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156 entry of a block is exported into the outer context. |
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157 *} |
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158 |
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159 notepad |
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160 begin |
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161 { |
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162 have a: A sorry |
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163 have b: B sorry |
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164 note a b |
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165 } |
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166 note this |
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167 note `A` |
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168 note `B` |
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169 end |
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170 |
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171 text {* Explicit blocks as well as implicit blocks of nested goal |
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172 statements (e.g.\ @{command have}) automatically introduce one extra |
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173 pair of parentheses in reserve. The @{command next} command allows |
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174 to ``jump'' between these sub-blocks. *} |
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175 |
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176 notepad |
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177 begin |
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178 |
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179 { |
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180 have a: A sorry |
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181 next |
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182 have b: B |
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183 proof - |
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184 show B sorry |
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185 next |
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186 have c: C sorry |
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187 next |
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188 have d: D sorry |
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189 qed |
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190 } |
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191 |
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192 txt {* Alternative version with explicit parentheses everywhere: *} |
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193 |
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194 { |
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195 { |
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196 have a: A sorry |
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197 } |
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198 { |
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199 have b: B |
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200 proof - |
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201 { |
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202 show B sorry |
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203 } |
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204 { |
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205 have c: C sorry |
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206 } |
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207 { |
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208 have d: D sorry |
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209 } |
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210 qed |
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211 } |
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212 } |
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213 |
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214 end |
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215 |
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216 |
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217 section {* Calculational reasoning \label{sec:calculations-synopsis} *} |
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218 |
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219 text {* |
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220 For example, see @{file "~~/src/HOL/Isar_Examples/Group.thy"}. |
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221 *} |
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222 |
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223 |
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224 subsection {* Special names in Isar proofs *} |
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225 |
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226 text {* |
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227 \begin{itemize} |
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228 |
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229 \item term @{text "?thesis"} --- the main conclusion of the |
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230 innermost pending claim |
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231 |
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232 \item term @{text "\<dots>"} --- the argument of the last explicitly |
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233 stated result (for infix application this is the right-hand side) |
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234 |
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235 \item fact @{text "this"} --- the last result produced in the text |
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236 |
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237 \end{itemize} |
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238 *} |
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239 |
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240 notepad |
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241 begin |
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242 have "x = y" |
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243 proof - |
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244 term ?thesis |
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245 show ?thesis sorry |
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246 term ?thesis -- {* static! *} |
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247 qed |
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248 term "\<dots>" |
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249 thm this |
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250 end |
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251 |
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252 text {* Calculational reasoning maintains the special fact called |
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253 ``@{text calculation}'' in the background. Certain language |
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254 elements combine primary @{text this} with secondary @{text |
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255 calculation}. *} |
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256 |
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257 |
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258 subsection {* Transitive chains *} |
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259 |
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260 text {* The Idea is to combine @{text this} and @{text calculation} |
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261 via typical @{text trans} rules (see also @{command |
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262 print_trans_rules}): *} |
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263 |
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264 thm trans |
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265 thm less_trans |
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266 thm less_le_trans |
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267 |
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268 notepad |
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269 begin |
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270 txt {* Plain bottom-up calculation: *} |
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271 have "a = b" sorry |
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272 also |
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273 have "b = c" sorry |
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274 also |
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275 have "c = d" sorry |
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276 finally |
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277 have "a = d" . |
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278 |
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279 txt {* Variant using the @{text "\<dots>"} abbreviation: *} |
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280 have "a = b" sorry |
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281 also |
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282 have "\<dots> = c" sorry |
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283 also |
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284 have "\<dots> = d" sorry |
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285 finally |
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286 have "a = d" . |
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287 |
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288 txt {* Top-down version with explicit claim at the head: *} |
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289 have "a = d" |
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290 proof - |
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291 have "a = b" sorry |
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292 also |
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293 have "\<dots> = c" sorry |
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294 also |
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295 have "\<dots> = d" sorry |
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296 finally |
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297 show ?thesis . |
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298 qed |
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299 next |
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300 txt {* Mixed inequalities (require suitable base type): *} |
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301 fix a b c d :: nat |
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302 |
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303 have "a < b" sorry |
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304 also |
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305 have "b \<le> c" sorry |
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306 also |
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307 have "c = d" sorry |
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308 finally |
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309 have "a < d" . |
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310 end |
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311 |
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312 |
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313 subsubsection {* Notes *} |
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314 |
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315 text {* |
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316 \begin{itemize} |
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317 |
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318 \item The notion of @{text trans} rule is very general due to the |
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319 flexibility of Isabelle/Pure rule composition. |
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320 |
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321 \item User applications may declare their own rules, with some care |
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322 about the operational details of higher-order unification. |
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323 |
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324 \end{itemize} |
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325 *} |
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326 |
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327 |
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328 subsection {* Degenerate calculations and bigstep reasoning *} |
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329 |
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330 text {* The Idea is to append @{text this} to @{text calculation}, |
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331 without rule composition. *} |
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332 |
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333 notepad |
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334 begin |
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335 txt {* A vacuous proof: *} |
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336 have A sorry |
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337 moreover |
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338 have B sorry |
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339 moreover |
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340 have C sorry |
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341 ultimately |
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342 have A and B and C . |
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343 next |
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344 txt {* Slightly more content (trivial bigstep reasoning): *} |
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345 have A sorry |
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346 moreover |
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347 have B sorry |
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348 moreover |
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349 have C sorry |
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350 ultimately |
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351 have "A \<and> B \<and> C" by blast |
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352 next |
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353 txt {* More ambitious bigstep reasoning involving structured results: *} |
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354 have "A \<or> B \<or> C" sorry |
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355 moreover |
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356 { assume A have R sorry } |
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357 moreover |
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358 { assume B have R sorry } |
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359 moreover |
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360 { assume C have R sorry } |
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361 ultimately |
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362 have R by blast -- {* ``big-bang integration'' of proof blocks (occasionally fragile) *} |
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363 end |
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364 |
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365 |
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366 section {* Induction *} |
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367 |
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368 subsection {* Induction as Natural Deduction *} |
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369 |
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370 text {* In principle, induction is just a special case of Natural |
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371 Deduction (see also \secref{sec:natural-deduction-synopsis}). For |
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372 example: *} |
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373 |
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374 thm nat.induct |
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375 print_statement nat.induct |
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376 |
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377 notepad |
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378 begin |
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379 fix n :: nat |
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380 have "P n" |
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381 proof (rule nat.induct) -- {* fragile rule application! *} |
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382 show "P 0" sorry |
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383 next |
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384 fix n :: nat |
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385 assume "P n" |
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386 show "P (Suc n)" sorry |
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387 qed |
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388 end |
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389 |
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390 text {* |
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391 In practice, much more proof infrastructure is required. |
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392 |
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393 The proof method @{method induct} provides: |
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394 \begin{itemize} |
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395 |
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396 \item implicit rule selection and robust instantiation |
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397 |
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398 \item context elements via symbolic case names |
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399 |
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400 \item support for rule-structured induction statements, with local |
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401 parameters, premises, etc. |
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402 |
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403 \end{itemize} |
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404 *} |
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405 |
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406 notepad |
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407 begin |
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408 fix n :: nat |
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409 have "P n" |
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410 proof (induct n) |
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411 case 0 |
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412 show ?case sorry |
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413 next |
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414 case (Suc n) |
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415 from Suc.hyps show ?case sorry |
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416 qed |
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417 end |
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418 |
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419 |
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420 subsubsection {* Example *} |
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421 |
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422 text {* |
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423 The subsequent example combines the following proof patterns: |
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424 \begin{itemize} |
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425 |
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426 \item outermost induction (over the datatype structure of natural |
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427 numbers), to decompose the proof problem in top-down manner |
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428 |
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429 \item calculational reasoning (\secref{sec:calculations-synopsis}) |
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430 to compose the result in each case |
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431 |
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432 \item solving local claims within the calculation by simplification |
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433 |
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434 \end{itemize} |
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435 *} |
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436 |
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437 lemma |
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438 fixes n :: nat |
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439 shows "(\<Sum>i=0..n. i) = n * (n + 1) div 2" |
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440 proof (induct n) |
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441 case 0 |
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442 have "(\<Sum>i=0..0. i) = (0::nat)" by simp |
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443 also have "\<dots> = 0 * (0 + 1) div 2" by simp |
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444 finally show ?case . |
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445 next |
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446 case (Suc n) |
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447 have "(\<Sum>i=0..Suc n. i) = (\<Sum>i=0..n. i) + (n + 1)" by simp |
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448 also have "\<dots> = n * (n + 1) div 2 + (n + 1)" by (simp add: Suc.hyps) |
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449 also have "\<dots> = (n * (n + 1) + 2 * (n + 1)) div 2" by simp |
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450 also have "\<dots> = (Suc n * (Suc n + 1)) div 2" by simp |
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451 finally show ?case . |
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452 qed |
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453 |
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454 text {* This demonstrates how induction proofs can be done without |
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455 having to consider the raw Natural Deduction structure. *} |
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456 |
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457 |
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458 subsection {* Induction with local parameters and premises *} |
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459 |
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460 text {* Idea: Pure rule statements are passed through the induction |
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461 rule. This achieves convenient proof patterns, thanks to some |
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462 internal trickery in the @{method induct} method. |
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463 |
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464 Important: Using compact HOL formulae with @{text "\<forall>/\<longrightarrow>"} is a |
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465 well-known anti-pattern! It would produce useless formal noise. |
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466 *} |
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467 |
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468 notepad |
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469 begin |
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470 fix n :: nat |
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471 fix P :: "nat \<Rightarrow> bool" |
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472 fix Q :: "'a \<Rightarrow> nat \<Rightarrow> bool" |
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473 |
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474 have "P n" |
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475 proof (induct n) |
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476 case 0 |
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477 show "P 0" sorry |
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478 next |
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479 case (Suc n) |
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480 from `P n` show "P (Suc n)" sorry |
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481 qed |
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482 |
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483 have "A n \<Longrightarrow> P n" |
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484 proof (induct n) |
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485 case 0 |
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486 from `A 0` show "P 0" sorry |
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487 next |
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488 case (Suc n) |
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489 from `A n \<Longrightarrow> P n` |
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490 and `A (Suc n)` show "P (Suc n)" sorry |
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491 qed |
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492 |
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493 have "\<And>x. Q x n" |
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494 proof (induct n) |
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495 case 0 |
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496 show "Q x 0" sorry |
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497 next |
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498 case (Suc n) |
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499 from `\<And>x. Q x n` show "Q x (Suc n)" sorry |
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500 txt {* Local quantification admits arbitrary instances: *} |
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501 note `Q a n` and `Q b n` |
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502 qed |
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503 end |
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504 |
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505 |
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506 subsection {* Implicit induction context *} |
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507 |
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508 text {* The @{method induct} method can isolate local parameters and |
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509 premises directly from the given statement. This is convenient in |
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510 practical applications, but requires some understanding of what is |
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511 going on internally (as explained above). *} |
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512 |
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513 notepad |
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514 begin |
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515 fix n :: nat |
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516 fix Q :: "'a \<Rightarrow> nat \<Rightarrow> bool" |
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517 |
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518 fix x :: 'a |
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519 assume "A x n" |
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520 then have "Q x n" |
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521 proof (induct n arbitrary: x) |
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522 case 0 |
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523 from `A x 0` show "Q x 0" sorry |
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524 next |
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525 case (Suc n) |
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526 from `\<And>x. A x n \<Longrightarrow> Q x n` -- {* arbitrary instances can be produced here *} |
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527 and `A x (Suc n)` show "Q x (Suc n)" sorry |
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528 qed |
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529 end |
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530 |
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531 |
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532 subsection {* Advanced induction with term definitions *} |
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533 |
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534 text {* Induction over subexpressions of a certain shape are delicate |
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535 to formalize. The Isar @{method induct} method provides |
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536 infrastructure for this. |
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537 |
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538 Idea: sub-expressions of the problem are turned into a defined |
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539 induction variable; often accompanied with fixing of auxiliary |
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540 parameters in the original expression. *} |
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541 |
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542 notepad |
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543 begin |
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544 fix a :: "'a \<Rightarrow> nat" |
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545 fix A :: "nat \<Rightarrow> bool" |
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546 |
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547 assume "A (a x)" |
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548 then have "P (a x)" |
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549 proof (induct "a x" arbitrary: x) |
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550 case 0 |
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551 note prem = `A (a x)` |
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552 and defn = `0 = a x` |
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553 show "P (a x)" sorry |
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554 next |
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555 case (Suc n) |
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556 note hyp = `\<And>x. n = a x \<Longrightarrow> A (a x) \<Longrightarrow> P (a x)` |
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557 and prem = `A (a x)` |
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558 and defn = `Suc n = a x` |
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559 show "P (a x)" sorry |
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560 qed |
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561 end |
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562 |
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563 |
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564 section {* Natural Deduction \label{sec:natural-deduction-synopsis} *} |
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565 |
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566 subsection {* Rule statements *} |
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567 |
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568 text {* |
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569 Isabelle/Pure ``theorems'' are always natural deduction rules, |
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570 which sometimes happen to consist of a conclusion only. |
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571 |
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572 The framework connectives @{text "\<And>"} and @{text "\<Longrightarrow>"} indicate the |
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573 rule structure declaratively. For example: *} |
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574 |
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575 thm conjI |
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576 thm impI |
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577 thm nat.induct |
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578 |
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579 text {* |
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580 The object-logic is embedded into the Pure framework via an implicit |
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581 derivability judgment @{term "Trueprop :: bool \<Rightarrow> prop"}. |
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582 |
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583 Thus any HOL formulae appears atomic to the Pure framework, while |
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584 the rule structure outlines the corresponding proof pattern. |
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585 |
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586 This can be made explicit as follows: |
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587 *} |
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588 |
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589 notepad |
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590 begin |
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591 write Trueprop ("Tr") |
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592 |
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593 thm conjI |
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594 thm impI |
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595 thm nat.induct |
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596 end |
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597 |
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598 text {* |
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599 Isar provides first-class notation for rule statements as follows. |
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600 *} |
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601 |
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602 print_statement conjI |
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603 print_statement impI |
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604 print_statement nat.induct |
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605 |
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606 |
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607 subsubsection {* Examples *} |
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608 |
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609 text {* |
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610 Introductions and eliminations of some standard connectives of |
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611 the object-logic can be written as rule statements as follows. (The |
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612 proof ``@{command "by"}~@{method blast}'' serves as sanity check.) |
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613 *} |
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614 |
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615 lemma "(P \<Longrightarrow> False) \<Longrightarrow> \<not> P" by blast |
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616 lemma "\<not> P \<Longrightarrow> P \<Longrightarrow> Q" by blast |
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617 |
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618 lemma "P \<Longrightarrow> Q \<Longrightarrow> P \<and> Q" by blast |
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619 lemma "P \<and> Q \<Longrightarrow> (P \<Longrightarrow> Q \<Longrightarrow> R) \<Longrightarrow> R" by blast |
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620 |
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621 lemma "P \<Longrightarrow> P \<or> Q" by blast |
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622 lemma "Q \<Longrightarrow> P \<or> Q" by blast |
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623 lemma "P \<or> Q \<Longrightarrow> (P \<Longrightarrow> R) \<Longrightarrow> (Q \<Longrightarrow> R) \<Longrightarrow> R" by blast |
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624 |
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625 lemma "(\<And>x. P x) \<Longrightarrow> (\<forall>x. P x)" by blast |
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626 lemma "(\<forall>x. P x) \<Longrightarrow> P x" by blast |
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627 |
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628 lemma "P x \<Longrightarrow> (\<exists>x. P x)" by blast |
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629 lemma "(\<exists>x. P x) \<Longrightarrow> (\<And>x. P x \<Longrightarrow> R) \<Longrightarrow> R" by blast |
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630 |
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631 lemma "x \<in> A \<Longrightarrow> x \<in> B \<Longrightarrow> x \<in> A \<inter> B" by blast |
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632 lemma "x \<in> A \<inter> B \<Longrightarrow> (x \<in> A \<Longrightarrow> x \<in> B \<Longrightarrow> R) \<Longrightarrow> R" by blast |
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633 |
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634 lemma "x \<in> A \<Longrightarrow> x \<in> A \<union> B" by blast |
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635 lemma "x \<in> B \<Longrightarrow> x \<in> A \<union> B" by blast |
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636 lemma "x \<in> A \<union> B \<Longrightarrow> (x \<in> A \<Longrightarrow> R) \<Longrightarrow> (x \<in> B \<Longrightarrow> R) \<Longrightarrow> R" by blast |
|
637 |
|
638 |
|
639 subsection {* Isar context elements *} |
|
640 |
|
641 text {* We derive some results out of the blue, using Isar context |
|
642 elements and some explicit blocks. This illustrates their meaning |
|
643 wrt.\ Pure connectives, without goal states getting in the way. *} |
|
644 |
|
645 notepad |
|
646 begin |
|
647 { |
|
648 fix x |
|
649 have "B x" sorry |
|
650 } |
|
651 have "\<And>x. B x" by fact |
|
652 |
|
653 next |
|
654 |
|
655 { |
|
656 assume A |
|
657 have B sorry |
|
658 } |
|
659 have "A \<Longrightarrow> B" by fact |
|
660 |
|
661 next |
|
662 |
|
663 { |
|
664 def x \<equiv> t |
|
665 have "B x" sorry |
|
666 } |
|
667 have "B t" by fact |
|
668 |
|
669 next |
|
670 |
|
671 { |
|
672 obtain x :: 'a where "B x" sorry |
|
673 have C sorry |
|
674 } |
|
675 have C by fact |
|
676 |
|
677 end |
|
678 |
|
679 |
|
680 subsection {* Pure rule composition *} |
|
681 |
|
682 text {* |
|
683 The Pure framework provides means for: |
|
684 |
|
685 \begin{itemize} |
|
686 |
|
687 \item backward-chaining of rules by @{inference resolution} |
|
688 |
|
689 \item closing of branches by @{inference assumption} |
|
690 |
|
691 \end{itemize} |
|
692 |
|
693 Both principles involve higher-order unification of @{text \<lambda>}-terms |
|
694 modulo @{text "\<alpha>\<beta>\<eta>"}-equivalence (cf.\ Huet and Miller). *} |
|
695 |
|
696 notepad |
|
697 begin |
|
698 assume a: A and b: B |
|
699 thm conjI |
|
700 thm conjI [of A B] -- "instantiation" |
|
701 thm conjI [of A B, OF a b] -- "instantiation and composition" |
|
702 thm conjI [OF a b] -- "composition via unification (trivial)" |
|
703 thm conjI [OF `A` `B`] |
|
704 |
|
705 thm conjI [OF disjI1] |
|
706 end |
|
707 |
|
708 text {* Note: Low-level rule composition is tedious and leads to |
|
709 unreadable~/ unmaintainable expressions in the text. *} |
|
710 |
|
711 |
|
712 subsection {* Structured backward reasoning *} |
|
713 |
|
714 text {* Idea: Canonical proof decomposition via @{command fix}~/ |
|
715 @{command assume}~/ @{command show}, where the body produces a |
|
716 natural deduction rule to refine some goal. *} |
|
717 |
|
718 notepad |
|
719 begin |
|
720 fix A B :: "'a \<Rightarrow> bool" |
|
721 |
|
722 have "\<And>x. A x \<Longrightarrow> B x" |
|
723 proof - |
|
724 fix x |
|
725 assume "A x" |
|
726 show "B x" sorry |
|
727 qed |
|
728 |
|
729 have "\<And>x. A x \<Longrightarrow> B x" |
|
730 proof - |
|
731 { |
|
732 fix x |
|
733 assume "A x" |
|
734 show "B x" sorry |
|
735 } -- "implicit block structure made explicit" |
|
736 note `\<And>x. A x \<Longrightarrow> B x` |
|
737 -- "side exit for the resulting rule" |
|
738 qed |
|
739 end |
|
740 |
|
741 |
|
742 subsection {* Structured rule application *} |
|
743 |
|
744 text {* |
|
745 Idea: Previous facts and new claims are composed with a rule from |
|
746 the context (or background library). |
|
747 *} |
|
748 |
|
749 notepad |
|
750 begin |
|
751 assume r1: "A \<Longrightarrow> B \<Longrightarrow> C" -- {* simple rule (Horn clause) *} |
|
752 |
|
753 have A sorry -- "prefix of facts via outer sub-proof" |
|
754 then have C |
|
755 proof (rule r1) |
|
756 show B sorry -- "remaining rule premises via inner sub-proof" |
|
757 qed |
|
758 |
|
759 have C |
|
760 proof (rule r1) |
|
761 show A sorry |
|
762 show B sorry |
|
763 qed |
|
764 |
|
765 have A and B sorry |
|
766 then have C |
|
767 proof (rule r1) |
|
768 qed |
|
769 |
|
770 have A and B sorry |
|
771 then have C by (rule r1) |
|
772 |
|
773 next |
|
774 |
|
775 assume r2: "A \<Longrightarrow> (\<And>x. B1 x \<Longrightarrow> B2 x) \<Longrightarrow> C" -- {* nested rule *} |
|
776 |
|
777 have A sorry |
|
778 then have C |
|
779 proof (rule r2) |
|
780 fix x |
|
781 assume "B1 x" |
|
782 show "B2 x" sorry |
|
783 qed |
|
784 |
|
785 txt {* The compound rule premise @{prop "\<And>x. B1 x \<Longrightarrow> B2 x"} is better |
|
786 addressed via @{command fix}~/ @{command assume}~/ @{command show} |
|
787 in the nested proof body. *} |
|
788 end |
|
789 |
|
790 |
|
791 subsection {* Example: predicate logic *} |
|
792 |
|
793 text {* |
|
794 Using the above principles, standard introduction and elimination proofs |
|
795 of predicate logic connectives of HOL work as follows. |
|
796 *} |
|
797 |
|
798 notepad |
|
799 begin |
|
800 have "A \<longrightarrow> B" and A sorry |
|
801 then have B .. |
|
802 |
|
803 have A sorry |
|
804 then have "A \<or> B" .. |
|
805 |
|
806 have B sorry |
|
807 then have "A \<or> B" .. |
|
808 |
|
809 have "A \<or> B" sorry |
|
810 then have C |
|
811 proof |
|
812 assume A |
|
813 then show C sorry |
|
814 next |
|
815 assume B |
|
816 then show C sorry |
|
817 qed |
|
818 |
|
819 have A and B sorry |
|
820 then have "A \<and> B" .. |
|
821 |
|
822 have "A \<and> B" sorry |
|
823 then have A .. |
|
824 |
|
825 have "A \<and> B" sorry |
|
826 then have B .. |
|
827 |
|
828 have False sorry |
|
829 then have A .. |
|
830 |
|
831 have True .. |
|
832 |
|
833 have "\<not> A" |
|
834 proof |
|
835 assume A |
|
836 then show False sorry |
|
837 qed |
|
838 |
|
839 have "\<not> A" and A sorry |
|
840 then have B .. |
|
841 |
|
842 have "\<forall>x. P x" |
|
843 proof |
|
844 fix x |
|
845 show "P x" sorry |
|
846 qed |
|
847 |
|
848 have "\<forall>x. P x" sorry |
|
849 then have "P a" .. |
|
850 |
|
851 have "\<exists>x. P x" |
|
852 proof |
|
853 show "P a" sorry |
|
854 qed |
|
855 |
|
856 have "\<exists>x. P x" sorry |
|
857 then have C |
|
858 proof |
|
859 fix a |
|
860 assume "P a" |
|
861 show C sorry |
|
862 qed |
|
863 |
|
864 txt {* Less awkward version using @{command obtain}: *} |
|
865 have "\<exists>x. P x" sorry |
|
866 then obtain a where "P a" .. |
|
867 end |
|
868 |
|
869 text {* Further variations to illustrate Isar sub-proofs involving |
|
870 @{command show}: *} |
|
871 |
|
872 notepad |
|
873 begin |
|
874 have "A \<and> B" |
|
875 proof -- {* two strictly isolated subproofs *} |
|
876 show A sorry |
|
877 next |
|
878 show B sorry |
|
879 qed |
|
880 |
|
881 have "A \<and> B" |
|
882 proof -- {* one simultaneous sub-proof *} |
|
883 show A and B sorry |
|
884 qed |
|
885 |
|
886 have "A \<and> B" |
|
887 proof -- {* two subproofs in the same context *} |
|
888 show A sorry |
|
889 show B sorry |
|
890 qed |
|
891 |
|
892 have "A \<and> B" |
|
893 proof -- {* swapped order *} |
|
894 show B sorry |
|
895 show A sorry |
|
896 qed |
|
897 |
|
898 have "A \<and> B" |
|
899 proof -- {* sequential subproofs *} |
|
900 show A sorry |
|
901 show B using `A` sorry |
|
902 qed |
|
903 end |
|
904 |
|
905 |
|
906 subsubsection {* Example: set-theoretic operators *} |
|
907 |
|
908 text {* There is nothing special about logical connectives (@{text |
|
909 "\<and>"}, @{text "\<or>"}, @{text "\<forall>"}, @{text "\<exists>"} etc.). Operators from |
|
910 set-theory or lattice-theory work analogously. It is only a matter |
|
911 of rule declarations in the library; rules can be also specified |
|
912 explicitly. |
|
913 *} |
|
914 |
|
915 notepad |
|
916 begin |
|
917 have "x \<in> A" and "x \<in> B" sorry |
|
918 then have "x \<in> A \<inter> B" .. |
|
919 |
|
920 have "x \<in> A" sorry |
|
921 then have "x \<in> A \<union> B" .. |
|
922 |
|
923 have "x \<in> B" sorry |
|
924 then have "x \<in> A \<union> B" .. |
|
925 |
|
926 have "x \<in> A \<union> B" sorry |
|
927 then have C |
|
928 proof |
|
929 assume "x \<in> A" |
|
930 then show C sorry |
|
931 next |
|
932 assume "x \<in> B" |
|
933 then show C sorry |
|
934 qed |
|
935 |
|
936 next |
|
937 have "x \<in> \<Inter>A" |
|
938 proof |
|
939 fix a |
|
940 assume "a \<in> A" |
|
941 show "x \<in> a" sorry |
|
942 qed |
|
943 |
|
944 have "x \<in> \<Inter>A" sorry |
|
945 then have "x \<in> a" |
|
946 proof |
|
947 show "a \<in> A" sorry |
|
948 qed |
|
949 |
|
950 have "a \<in> A" and "x \<in> a" sorry |
|
951 then have "x \<in> \<Union>A" .. |
|
952 |
|
953 have "x \<in> \<Union>A" sorry |
|
954 then obtain a where "a \<in> A" and "x \<in> a" .. |
|
955 end |
|
956 |
|
957 |
|
958 section {* Generalized elimination and cases *} |
|
959 |
|
960 subsection {* General elimination rules *} |
|
961 |
|
962 text {* |
|
963 The general format of elimination rules is illustrated by the |
|
964 following typical representatives: |
|
965 *} |
|
966 |
|
967 thm exE -- {* local parameter *} |
|
968 thm conjE -- {* local premises *} |
|
969 thm disjE -- {* split into cases *} |
|
970 |
|
971 text {* |
|
972 Combining these characteristics leads to the following general scheme |
|
973 for elimination rules with cases: |
|
974 |
|
975 \begin{itemize} |
|
976 |
|
977 \item prefix of assumptions (or ``major premises'') |
|
978 |
|
979 \item one or more cases that enable to establish the main conclusion |
|
980 in an augmented context |
|
981 |
|
982 \end{itemize} |
|
983 *} |
|
984 |
|
985 notepad |
|
986 begin |
|
987 assume r: |
|
988 "A1 \<Longrightarrow> A2 \<Longrightarrow> (* assumptions *) |
|
989 (\<And>x y. B1 x y \<Longrightarrow> C1 x y \<Longrightarrow> R) \<Longrightarrow> (* case 1 *) |
|
990 (\<And>x y. B2 x y \<Longrightarrow> C2 x y \<Longrightarrow> R) \<Longrightarrow> (* case 2 *) |
|
991 R (* main conclusion *)" |
|
992 |
|
993 have A1 and A2 sorry |
|
994 then have R |
|
995 proof (rule r) |
|
996 fix x y |
|
997 assume "B1 x y" and "C1 x y" |
|
998 show ?thesis sorry |
|
999 next |
|
1000 fix x y |
|
1001 assume "B2 x y" and "C2 x y" |
|
1002 show ?thesis sorry |
|
1003 qed |
|
1004 end |
|
1005 |
|
1006 text {* Here @{text "?thesis"} is used to refer to the unchanged goal |
|
1007 statement. *} |
|
1008 |
|
1009 |
|
1010 subsection {* Rules with cases *} |
|
1011 |
|
1012 text {* |
|
1013 Applying an elimination rule to some goal, leaves that unchanged |
|
1014 but allows to augment the context in the sub-proof of each case. |
|
1015 |
|
1016 Isar provides some infrastructure to support this: |
|
1017 |
|
1018 \begin{itemize} |
|
1019 |
|
1020 \item native language elements to state eliminations |
|
1021 |
|
1022 \item symbolic case names |
|
1023 |
|
1024 \item method @{method cases} to recover this structure in a |
|
1025 sub-proof |
|
1026 |
|
1027 \end{itemize} |
|
1028 *} |
|
1029 |
|
1030 print_statement exE |
|
1031 print_statement conjE |
|
1032 print_statement disjE |
|
1033 |
|
1034 lemma |
|
1035 assumes A1 and A2 -- {* assumptions *} |
|
1036 obtains |
|
1037 (case1) x y where "B1 x y" and "C1 x y" |
|
1038 | (case2) x y where "B2 x y" and "C2 x y" |
|
1039 sorry |
|
1040 |
|
1041 |
|
1042 subsubsection {* Example *} |
|
1043 |
|
1044 lemma tertium_non_datur: |
|
1045 obtains |
|
1046 (T) A |
|
1047 | (F) "\<not> A" |
|
1048 by blast |
|
1049 |
|
1050 notepad |
|
1051 begin |
|
1052 fix x y :: 'a |
|
1053 have C |
|
1054 proof (cases "x = y" rule: tertium_non_datur) |
|
1055 case T |
|
1056 from `x = y` show ?thesis sorry |
|
1057 next |
|
1058 case F |
|
1059 from `x \<noteq> y` show ?thesis sorry |
|
1060 qed |
|
1061 end |
|
1062 |
|
1063 |
|
1064 subsubsection {* Example *} |
|
1065 |
|
1066 text {* |
|
1067 Isabelle/HOL specification mechanisms (datatype, inductive, etc.) |
|
1068 provide suitable derived cases rules. |
|
1069 *} |
|
1070 |
|
1071 datatype foo = Foo | Bar foo |
|
1072 |
|
1073 notepad |
|
1074 begin |
|
1075 fix x :: foo |
|
1076 have C |
|
1077 proof (cases x) |
|
1078 case Foo |
|
1079 from `x = Foo` show ?thesis sorry |
|
1080 next |
|
1081 case (Bar a) |
|
1082 from `x = Bar a` show ?thesis sorry |
|
1083 qed |
|
1084 end |
|
1085 |
|
1086 |
|
1087 subsection {* Obtaining local contexts *} |
|
1088 |
|
1089 text {* A single ``case'' branch may be inlined into Isar proof text |
|
1090 via @{command obtain}. This proves @{prop "(\<And>x. B x \<Longrightarrow> thesis) \<Longrightarrow> |
|
1091 thesis"} on the spot, and augments the context afterwards. *} |
|
1092 |
|
1093 notepad |
|
1094 begin |
|
1095 fix B :: "'a \<Rightarrow> bool" |
|
1096 |
|
1097 obtain x where "B x" sorry |
|
1098 note `B x` |
|
1099 |
|
1100 txt {* Conclusions from this context may not mention @{term x} again! *} |
|
1101 { |
|
1102 obtain x where "B x" sorry |
|
1103 from `B x` have C sorry |
|
1104 } |
|
1105 note `C` |
|
1106 end |
|
1107 |
|
1108 end |